Quality control systems that safeguard cellular integrity are essential for life. DNA repair and damage re-sponse pathways rank among the cell’s principal surveillance systems as they ensure not only the safe stor-age and accurate transmission of its genetic information, but also the correct translation of the genetic code to produce the structural and enzymatic components of the cell. Beyond their protective functions, DNA repair systems contribute to a variety of regulatory processes, such as the control of gene expression via epigenetic DNA modifications or the generation of diversity in the immune system. Consequently, deficien-cies in genome maintenance result in a variety of disorders, ranging from various malignancies to immuno-logical and neurological disorders and accelerated ageing. Understanding how DNA repair and damage sig-nalling are regulated is therefore key to our efforts to promote human health.The objective of the CRC 1361 is to elucidate the regulatory mechanisms governing the choice between individual genome maintenance pathways, their fidelity, their interdependencies and their contributions to cellular physiology. During its first funding period, the CRC has made critical advances in characterising components of DNA repair and damage signalling systems as decision-makers in the regulation of genome maintenance. In particular, our research has highlighted the relevance of endogenous factors as sources of genome instability. In the next funding period, the CRC aims to deepen its mechanistic analysis of genome maintenance systems and intensify efforts to draw functional connections between individual repair path-ways to integrate them into larger regulatory networks. This will require enhanced systems-level approaches to identify expanded protein-DNA and protein-protein interaction networks and to determine the genome-wide distribution of lesions to gain an understanding of their implications in a larger context. The CRC’s dedi-cated service platforms in Quantitative Proteomics and Genomics & Bioinformatics have been essential col-laboration partners in the development of this technology and will continue to act as critical supporting struc-tures for the planned research. With their contributions, we will focus our investigation primarily on the vari-ous endogenous sources of genome instability, their perception by cellular signalling pathways, their processing by dedicated or overlapping DNA repair pathways and their implications for cell fate and physiology. The interdisciplinary nature of the CRC, spanning structural and molecular biology, biochemistry, genetics and genomics, cell biology, toxicology and computational biology, will contribute to the consolidation of Mainz as a hub of genome stability research and ensure a high-quality education for the next generation of scientists in the field.

DFG Programme Collaborative Research Centres

• 02 - Formation and analysis of DNA-protein crosslinks (Project Head Carell, Thomas )
• 05 - Genome-wide analysis of DNA damage and impact of SCARS during maintenance of genotoxic stress-induced senescence (Project Head Christmann, Markus )
• 06 - Dissecting the response of replisomes to genotoxic stress (Project Head Cardoso, Maria Cristina )
• 07 - Genome-wide analysis of DNA damage, repair and replication stress (Project Head Ulrich, Ph.D., Helle )
• 08 - Role of SPRTN in resolution of DNA protein crosslinks and replication stress (Project Head Dikic, Ivan )
• 09 - The analysis of DNA repair at sites of single ribonucleotide insertions (Project Head Luke, Ph.D., Brian )
• 11 - Analysis of the PP2A-PR130 complex as novel regulator of cell fate and DNA repair pathway choice upon DNA replication stress (Project Head Krämer, Oliver Holger )
• 12 - Mechanisms opposing genomic instability arising from dysregulated G4s and R-loops (Project Head Beli, Petra )
• 13 - Sources and consequences of intrinsic genomic instability across human cell types (Project Heads Roukos, Vassilis ;  Zarnack, Katharina )
• 15 - Roles of helicases and recombinases in homologous recombination pathway choice (Project Head Löbrich, Markus )
• 17 - Functions of RNA in double-strand break repair and DNA end protection (Project Heads Baumann, Ph.D., Peter ;  Luke, Ph.D., Brian )
• 18 - Structural mechanism of MRN-ATM in DNA double-strand break signalling and processing (Project Head Hopfner, Karl-Peter )
• 19 - Deconstructing the role of HIPK2 in DNA repair and genome stability (Project Head Hofmann, Ph.D., Thomas G. )
• 20 - Mechanism and biological function of mammalian DNA Poly-ADP-ribosylation (Project Head Niehrs, Ph.D., Christof )
• 21 - Global-genome repair of DNA-protein crosslinks: lesion detection and pathway choice (Project Head Stingele, Julian )
• 22 - Transposon-induced DNA damage in development and disease (Project Head Barau, Ph.D., Joan )
• 23 - Systematic investigation of the role of BAF complexes in genome stability (Project Heads Luck, Katja ;  Schick-Nickolaus, Sandra )
• MGK - Integrated Research Training Group (Project Heads Dahm, Ralf ;  Niehrs, Ph.D., Christof )
• Z02 - Service project: Quantitative proteomics (Project Heads Beli, Petra ;  Butter, Falk ;  Chen, Jiaxuan )
• Z03 - Service project: Genomics & bioinformatics (Project Heads Karaulanov, Emil ;  Méndez-Lago, Maria )
• Z04 - Service Project: Central management (Project Head Ulrich, Ph.D., Helle )

• 01 - Quantitative interactomics of specific types of DNA damage (Project Head Butter, Falk )
• 03 - Role of NEIL DNA glycosylases in DNA demethylation and base excision repair (Project Head Niehrs, Ph.D., Christof )
• 04 - Co-transcriptional repair and transcriptional bypass of bulky DNA adducts (Project Head Khobta, Andriy )
• 10 - Structure-function analyses of mammalian Timeless in genome maintenance (Project Head Wolf, Eva )
• 14 - Quantitative time-resolved analysis of DSB repair in individual living cells (Project Head Loewer, Alexander )
• Z01 - Service project: DNA damage & repair assays (Project Heads Christmann, Markus ;  Roos, Wynand P. )

Applicant Institution Johannes Gutenberg-Universität Mainz

Participating University Goethe-Universität Frankfurt am Main; Ludwig-Maximilians-Universität München; Technische Universität Darmstadt

Spokesperson Professorin Dr. Helle Ulrich, Ph.D.